/* Copyright (C) 2011 J. Coliz This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License version 2 as published by the Free Software Foundation. */ /** * @file RF24.h * * Class declaration for RF24 and helper enums */ #ifndef __RF24_H__ #define __RF24_H__ #include "RF24_config.h" #if defined (RF24_LINUX) || defined (LITTLEWIRE) #include "utility/includes.h" #elif defined SOFTSPI #include #endif /** * Power Amplifier level. * * For use with setPALevel() */ typedef enum { RF24_PA_MIN = 0, RF24_PA_LOW, RF24_PA_HIGH, RF24_PA_MAX, RF24_PA_ERROR } rf24_pa_dbm_e; /** * Data rate. How fast data moves through the air. * * For use with setDataRate() */ typedef enum { RF24_1MBPS = 0, RF24_2MBPS, RF24_250KBPS } rf24_datarate_e; /** * CRC Length. How big (if any) of a CRC is included. * * For use with setCRCLength() */ typedef enum { RF24_CRC_DISABLED = 0, RF24_CRC_8, RF24_CRC_16 } rf24_crclength_e; /** * Driver for nRF24L01(+) 2.4GHz Wireless Transceiver */ class RF24 { private: #ifdef SOFTSPI SoftSPI spi; #elif defined (SPI_UART) SPIUARTClass uspi; #endif #if defined (RF24_LINUX) || defined (XMEGA_D3) /* XMEGA can use SPI class */ SPI spi; #endif #if defined (MRAA) GPIO gpio; #endif uint16_t ce_pin; /**< "Chip Enable" pin, activates the RX or TX role */ uint16_t csn_pin; /**< SPI Chip select */ uint32_t spi_speed; /**< SPI Bus Speed */ #if defined (RF24_LINUX) || defined (XMEGA_D3) uint8_t spi_rxbuff[32+1] ; //SPI receive buffer (payload max 32 bytes) uint8_t spi_txbuff[32+1] ; //SPI transmit buffer (payload max 32 bytes + 1 byte for the command) #endif uint8_t payload_size; /**< Fixed size of payloads */ bool dynamic_payloads_enabled; /**< Whether dynamic payloads are enabled. */ bool ack_payloads_enabled; /**< Whether ack payloads are enabled. */ uint8_t pipe0_reading_address[5]; /**< Last address set on pipe 0 for reading. */ uint8_t addr_width; /**< The address width to use - 3,4 or 5 bytes. */ uint8_t config_reg; /**< For storing the value of the NRF_CONFIG register */ protected: /** * SPI transactions * * Common code for SPI transactions including CSN toggle * */ inline void beginTransaction(); inline void endTransaction(); public: /** * @name Primary public interface * * These are the main methods you need to operate the chip */ /**@{*/ /** * RF24 Constructor * * Creates a new instance of this driver. Before using, you create an instance * and send in the unique pins that this chip is connected to. * * See http://tmrh20.github.io/RF24/pages.html for device specific information
* * @note Users can specify default SPI speed by modifying `#define RF24_SPI_SPEED` in RF24_config.h
* For Arduino, SPI speed will only be properly configured this way on devices supporting SPI TRANSACTIONS
* Older/Unsupported Arduino devices will use a default clock divider & settings configuration
* Linux: The old way of setting SPI speeds using BCM2835 driver enums has been removed
* * @param _cepin The pin attached to Chip Enable on the RF module * @param _cspin The pin attached to Chip Select * @param _spispeed The SPI speed in Hz ie: 1000000 == 1Mhz */ RF24(uint16_t _cepin, uint16_t _cspin, uint32_t _spispeed = RF24_SPI_SPEED); #if defined (RF24_LINUX) virtual ~RF24() {}; #endif /** * Begin operation of the chip * * Call this in setup(), before calling any other methods. * @code radio.begin() @endcode */ bool begin(void); /** * Checks if the chip is connected to the SPI bus */ bool isChipConnected(); /** * Start listening on the pipes opened for reading. * * 1. Be sure to call openReadingPipe() first. * 2. Do not call write() while in this mode, without first calling stopListening(). * 3. Call available() to check for incoming traffic, and read() to get it. * * @code * Open reading pipe 1 using address CCCECCCECC * * byte address[] = { 0xCC,0xCE,0xCC,0xCE,0xCC }; * radio.openReadingPipe(1,address); * radio.startListening(); * @endcode */ void startListening(void); /** * Stop listening for incoming messages, and switch to transmit mode. * * Do this before calling write(). * @code * radio.stopListening(); * radio.write(&data,sizeof(data)); * @endcode */ void stopListening(void); /** * Check whether there are bytes available to be read * @code * if(radio.available()){ * radio.read(&data,sizeof(data)); * } * @endcode * @return True if there is a payload available, false if none is */ bool available(void); /** * Read from the available payload * * The length of data read should the next available payload's length * @sa getPayloadSize(), getDynamicPayloadSize() * * @note I specifically chose 'void*' as a data type to make it easier * for beginners to use. No casting needed. * * @note No longer boolean. Use available to determine if packets are * available. Interrupt flags are now cleared during reads instead of * when calling available(). * * @param buf Pointer to a buffer where the data should be written * @param len Maximum number of bytes to read into the buffer. This * value should match the length of the object referenced using the * `buf` parameter. There is no bounds checking implemented here. * * @code * if(radio.available()){ * radio.read(&data,sizeof(data)); * } * @endcode * @return No return value. Use available(). * @remark Remember that each call to read() fetches data from the * RX FIFO beginning with the first byte from the first available * payload. A payload is not removed from the RX FIFO until it's * entire length (or more) is fetched using read(). * @remarks * - If `len` parameter's value is less than the available payload's * length, then the payload remains in the RX FIFO. * - If `len` parameter's value is greater than the first of multiple * available payloads, then the data returned to the `buf` * parameter's object will be supplemented with data from the next * available payload. * - If `len` parameter's value is greater than the last available * payload's length, then the last byte in the payload is used as * padding for the data returned to the `buf` parameter's object. * The nRF24L01 will continue returning the last byte from the last * payload even when read() is called with an empty RX FIFO. */ void read(void* buf, uint8_t len); /** * Be sure to call openWritingPipe() first to set the destination * of where to write to. * * This blocks until the message is successfully acknowledged by * the receiver or the timeout/retransmit maxima are reached. In * the current configuration, the max delay here is 60-70ms. * * The maximum size of data written is the fixed payload size, see * getPayloadSize(). However, you can write less, and the remainder * will just be filled with zeroes. * * TX/RX/RT interrupt flags will be cleared every time write is called * * @param buf Pointer to the data to be sent * @param len Number of bytes to be sent * * @code * radio.stopListening(); * radio.write(&data,sizeof(data)); * @endcode * @return True if the payload was delivered successfully and an ACK was received, or upon successfull transmission if auto-ack is disabled. */ bool write(const void* buf, uint8_t len); /** * New: Open a pipe for writing via byte array. Old addressing format retained * for compatibility. * * Only one writing pipe can be open at once, but you can change the address * you'll write to. Call stopListening() first. * * Addresses are assigned via a byte array, default is 5 byte address length s * * @code * uint8_t addresses[][6] = {"1Node","2Node"}; * radio.openWritingPipe(addresses[0]); * @endcode * @code * uint8_t address[] = { 0xCC,0xCE,0xCC,0xCE,0xCC }; * radio.openWritingPipe(address); * address[0] = 0x33; * radio.openReadingPipe(1,address); * @endcode * @see setAddressWidth * * @param address The address of the pipe to open. Coordinate these pipe * addresses amongst nodes on the network. */ void openWritingPipe(const uint8_t* address); /** * Open a pipe for reading * * Up to 6 pipes can be open for reading at once. Open all the required * reading pipes, and then call startListening(). * * @see openWritingPipe * @see setAddressWidth * * @note Pipes 0 and 1 will store a full 5-byte address. Pipes 2-5 will technically * only store a single byte, borrowing up to 4 additional bytes from pipe #1 per the * assigned address width. * @warning Pipes 1-5 should share the same address, except the first byte. * Only the first byte in the array should be unique, e.g. * @code * uint8_t addresses[][6] = {"1Node","2Node"}; * openReadingPipe(1,addresses[0]); * openReadingPipe(2,addresses[1]); * @endcode * * @warning Pipe 0 is also used by the writing pipe so should typically be avoided as a reading pipe.
* If used, the reading pipe 0 address needs to be restored at avery call to startListening(), and the address
* is ONLY restored if the LSB is a non-zero value.
See http://maniacalbits.blogspot.com/2013/04/rf24-addressing-nrf24l01-radios-require.html * * @param number Which pipe# to open, 0-5. * @param address The 24, 32 or 40 bit address of the pipe to open. */ void openReadingPipe(uint8_t number, const uint8_t* address); /**@}*/ /** * @name Advanced Operation * * Methods you can use to drive the chip in more advanced ways */ /**@{*/ /** * Print a giant block of debugging information to stdout * * @warning Does nothing if stdout is not defined. See fdevopen in stdio.h * The printf.h file is included with the library for Arduino. * @code * #include * setup(){ * Serial.begin(115200); * printf_begin(); * ... * } * @endcode */ void printDetails(void); /** * Test whether there are bytes available to be read in the * FIFO buffers. * * @param[out] pipe_num Which pipe has the payload available * * @code * uint8_t pipeNum; * if(radio.available(&pipeNum)){ * radio.read(&data,sizeof(data)); * Serial.print("Got data on pipe"); * Serial.println(pipeNum); * } * @endcode * @return True if there is a payload available, false if none is */ bool available(uint8_t* pipe_num); /** * Check if the radio needs to be read. Can be used to prevent data loss * @return True if all three 32-byte radio buffers are full */ bool rxFifoFull(); /** * Enter low-power mode * * To return to normal power mode, call powerUp(). * * @note After calling startListening(), a basic radio will consume about 13.5mA * at max PA level. * During active transmission, the radio will consume about 11.5mA, but this will * be reduced to 26uA (.026mA) between sending. * In full powerDown mode, the radio will consume approximately 900nA (.0009mA) * * @code * radio.powerDown(); * avr_enter_sleep_mode(); // Custom function to sleep the device * radio.powerUp(); * @endcode */ void powerDown(void); /** * Leave low-power mode - required for normal radio operation after calling powerDown() * * To return to low power mode, call powerDown(). * @note This will take up to 5ms for maximum compatibility */ void powerUp(void); /** * Write for single NOACK writes. Optionally disables acknowledgements/autoretries for a single write. * * @note enableDynamicAck() must be called to enable this feature * * Can be used with enableAckPayload() to request a response * @see enableDynamicAck() * @see setAutoAck() * @see write() * * @param buf Pointer to the data to be sent * @param len Number of bytes to be sent * @param multicast Request ACK (0), NOACK (1) */ bool write(const void* buf, uint8_t len, const bool multicast); /** * This will not block until the 3 FIFO buffers are filled with data. * Once the FIFOs are full, writeFast will simply wait for success or * timeout, and return 1 or 0 respectively. From a user perspective, just * keep trying to send the same data. The library will keep auto retrying * the current payload using the built in functionality. * @warning It is important to never keep the nRF24L01 in TX mode and FIFO full for more than 4ms at a time. If the auto * retransmit is enabled, the nRF24L01 is never in TX mode long enough to disobey this rule. Allow the FIFO * to clear by issuing txStandBy() or ensure appropriate time between transmissions. * * @code * Example (Partial blocking): * * radio.writeFast(&buf,32); // Writes 1 payload to the buffers * txStandBy(); // Returns 0 if failed. 1 if success. Blocks only until MAX_RT timeout or success. Data flushed on fail. * * radio.writeFast(&buf,32); // Writes 1 payload to the buffers * txStandBy(1000); // Using extended timeouts, returns 1 if success. Retries failed payloads for 1 seconds before returning 0. * @endcode * * @see txStandBy() * @see write() * @see writeBlocking() * * @param buf Pointer to the data to be sent * @param len Number of bytes to be sent * @return True if the payload was delivered successfully false if not */ bool writeFast(const void* buf, uint8_t len); /** * WriteFast for single NOACK writes. Disables acknowledgements/autoretries for a single write. * * @note enableDynamicAck() must be called to enable this feature * @see enableDynamicAck() * @see setAutoAck() * * @param buf Pointer to the data to be sent * @param len Number of bytes to be sent * @param multicast Request ACK (0) or NOACK (1) */ bool writeFast(const void* buf, uint8_t len, const bool multicast); /** * This function extends the auto-retry mechanism to any specified duration. * It will not block until the 3 FIFO buffers are filled with data. * If so the library will auto retry until a new payload is written * or the user specified timeout period is reached. * @warning It is important to never keep the nRF24L01 in TX mode and FIFO full for more than 4ms at a time. If the auto * retransmit is enabled, the nRF24L01 is never in TX mode long enough to disobey this rule. Allow the FIFO * to clear by issuing txStandBy() or ensure appropriate time between transmissions. * * @code * Example (Full blocking): * * radio.writeBlocking(&buf,32,1000); //Wait up to 1 second to write 1 payload to the buffers * txStandBy(1000); //Wait up to 1 second for the payload to send. Return 1 if ok, 0 if failed. * //Blocks only until user timeout or success. Data flushed on fail. * @endcode * @note If used from within an interrupt, the interrupt should be disabled until completion, and sei(); called to enable millis(). * @see txStandBy() * @see write() * @see writeFast() * * @param buf Pointer to the data to be sent * @param len Number of bytes to be sent * @param timeout User defined timeout in milliseconds. * @return True if the payload was loaded into the buffer successfully false if not */ bool writeBlocking(const void* buf, uint8_t len, uint32_t timeout); /** * This function should be called as soon as transmission is finished to * drop the radio back to STANDBY-I mode. If not issued, the radio will * remain in STANDBY-II mode which, per the data sheet, is not a recommended * operating mode. * * @note When transmitting data in rapid succession, it is still recommended by * the manufacturer to drop the radio out of TX or STANDBY-II mode if there is * time enough between sends for the FIFOs to empty. This is not required if auto-ack * is enabled. * * Relies on built-in auto retry functionality. * * @code * Example (Partial blocking): * * radio.writeFast(&buf,32); * radio.writeFast(&buf,32); * radio.writeFast(&buf,32); //Fills the FIFO buffers up * bool ok = txStandBy(); //Returns 0 if failed. 1 if success. * //Blocks only until MAX_RT timeout or success. Data flushed on fail. * @endcode * @see txStandBy(unsigned long timeout) * @return True if transmission is successful * */ bool txStandBy(); /** * This function allows extended blocking and auto-retries per a user defined timeout * @code * Fully Blocking Example: * * radio.writeFast(&buf,32); * radio.writeFast(&buf,32); * radio.writeFast(&buf,32); //Fills the FIFO buffers up * bool ok = txStandBy(1000); //Returns 0 if failed after 1 second of retries. 1 if success. * //Blocks only until user defined timeout or success. Data flushed on fail. * @endcode * @note If used from within an interrupt, the interrupt should be disabled until completion, and sei(); called to enable millis(). * @param timeout Number of milliseconds to retry failed payloads * @param startTx If this is set to `true`, then this function puts the nRF24L01 * in TX Mode. `false` leaves the primary mode (TX or RX) as it is, which can * prevent the mandatory wait time to change modes. * @return True if transmission is successful * */ bool txStandBy(uint32_t timeout, bool startTx = 0); /** * Write an ack payload for the specified pipe * * The next time a message is received on @p pipe, the data in @p buf will * be sent back in the acknowledgement. * @see enableAckPayload() * @see enableDynamicPayloads() * @warning Only three of these can be pending at any time as there are only 3 FIFO buffers.
Dynamic payloads must be enabled. * @note Ack payloads are handled automatically by the radio chip when a payload is received. Users should generally * write an ack payload as soon as startListening() is called, so one is available when a regular payload is received. * @note Ack payloads are dynamic payloads. This only works on pipes 0&1 by default. Call * enableDynamicPayloads() to enable on all pipes. * * @param pipe Which pipe# (typically 1-5) will get this response. * @param buf Pointer to data that is sent * @param len Length of the data to send, up to 32 bytes max. Not affected * by the static payload set by setPayloadSize(). */ void writeAckPayload(uint8_t pipe, const void* buf, uint8_t len); /** * Determine if an ack payload was received in the most recent call to * write(). The regular available() can also be used. * * Call read() to retrieve the ack payload. * * @return True if an ack payload is available. */ bool isAckPayloadAvailable(void); /** * Call this when you get an interrupt to find out why * * Tells you what caused the interrupt, and clears the state of * interrupts. * * @param[out] tx_ok The send was successful (TX_DS) * @param[out] tx_fail The send failed, too many retries (MAX_RT) * @param[out] rx_ready There is a message waiting to be read (RX_DS) */ void whatHappened(bool& tx_ok, bool& tx_fail, bool& rx_ready); /** * Non-blocking write to the open writing pipe used for buffered writes * * @note Optimization: This function now leaves the CE pin high, so the radio * will remain in TX or STANDBY-II Mode until a txStandBy() command is issued. Can be used as an alternative to startWrite() * if writing multiple payloads at once. * @warning It is important to never keep the nRF24L01 in TX mode with FIFO full for more than 4ms at a time. If the auto * retransmit/autoAck is enabled, the nRF24L01 is never in TX mode long enough to disobey this rule. Allow the FIFO * to clear by issuing txStandBy() or ensure appropriate time between transmissions. * * @see write() * @see writeFast() * @see startWrite() * @see writeBlocking() * * For single noAck writes see: * @see enableDynamicAck() * @see setAutoAck() * * @param buf Pointer to the data to be sent * @param len Number of bytes to be sent * @param multicast Request ACK (0) or NOACK (1) * @param startTx If this is set to `true`, then this function sets the * nRF24L01's CE pin to active (enabling TX transmissions). `false` has no * effect on the nRF24L01's CE pin. * @return True if the payload was delivered successfully false if not */ void startFastWrite(const void* buf, uint8_t len, const bool multicast, bool startTx = 1); /** * Non-blocking write to the open writing pipe * * Just like write(), but it returns immediately. To find out what happened * to the send, catch the IRQ and then call whatHappened(). * * @see write() * @see writeFast() * @see startFastWrite() * @see whatHappened() * * For single noAck writes see: * @see enableDynamicAck() * @see setAutoAck() * * @param buf Pointer to the data to be sent * @param len Number of bytes to be sent * @param multicast Request ACK (0) or NOACK (1) * */ void startWrite(const void* buf, uint8_t len, const bool multicast); /** * This function is mainly used internally to take advantage of the auto payload * re-use functionality of the chip, but can be beneficial to users as well. * * The function will instruct the radio to re-use the data in the FIFO buffers, * and instructs the radio to re-send once the timeout limit has been reached. * Used by writeFast and writeBlocking to initiate retries when a TX failure * occurs. Retries are automatically initiated except with the standard write(). * This way, data is not flushed from the buffer until switching between modes. * * @note This is to be used AFTER auto-retry fails if wanting to resend * using the built-in payload reuse features. * After issuing reUseTX(), it will keep reending the same payload forever or until * a payload is written to the FIFO, or a flush_tx command is given. */ void reUseTX(); /** * Empty the transmit buffer. This is generally not required in standard operation. * May be required in specific cases after stopListening() , if operating at 250KBPS data rate. * * @return Current value of status register */ uint8_t flush_tx(void); /** * Test whether there was a carrier on the line for the * previous listening period. * * Useful to check for interference on the current channel. * * @return true if was carrier, false if not */ bool testCarrier(void); /** * Test whether a signal (carrier or otherwise) greater than * or equal to -64dBm is present on the channel. Valid only * on nRF24L01P (+) hardware. On nRF24L01, use testCarrier(). * * Useful to check for interference on the current channel and * channel hopping strategies. * * @code * bool goodSignal = radio.testRPD(); * if(radio.available()){ * Serial.println(goodSignal ? "Strong signal > 64dBm" : "Weak signal < 64dBm" ); * radio.read(0,0); * } * @endcode * @return true if signal => -64dBm, false if not */ bool testRPD(void); /** * Test whether this is a real radio, or a mock shim for * debugging. Setting either pin to 0xff is the way to * indicate that this is not a real radio. * * @return true if this is a legitimate radio */ bool isValid() { return ce_pin != 0xff && csn_pin != 0xff; } /** * Close a pipe after it has been previously opened. * Can be safely called without having previously opened a pipe. * @param pipe Which pipe # to close, 0-5. */ void closeReadingPipe(uint8_t pipe); /** * * If a failure has been detected, it usually indicates a hardware issue. By default the library * will cease operation when a failure is detected. * This should allow advanced users to detect and resolve intermittent hardware issues. * * In most cases, the radio must be re-enabled via radio.begin(); and the appropriate settings * applied after a failure occurs, if wanting to re-enable the device immediately. * * The three main failure modes of the radio include: * * Writing to radio: Radio unresponsive - Fixed internally by adding a timeout to the internal write functions in RF24 (failure handling) * * Reading from radio: Available returns true always - Fixed by adding a timeout to available functions by the user. This is implemented internally in RF24Network. * * Radio configuration settings are lost - Fixed by monitoring a value that is different from the default, and re-configuring the radio if this setting reverts to the default. * * See the included example, GettingStarted_HandlingFailures * * @code * if(radio.failureDetected){ * radio.begin(); // Attempt to re-configure the radio with defaults * radio.failureDetected = 0; // Reset the detection value * radio.openWritingPipe(addresses[1]); // Re-configure pipe addresses * radio.openReadingPipe(1,addresses[0]); * report_failure(); // Blink leds, send a message, etc. to indicate failure * } * @endcode */ //#if defined (FAILURE_HANDLING) bool failureDetected; //#endif /**@}*/ /** * @name Optional Configurators * * Methods you can use to get or set the configuration of the chip. * None are required. Calling begin() sets up a reasonable set of * defaults. */ /**@{*/ /** * Set the address width from 3 to 5 bytes (24, 32 or 40 bit) * * @param a_width The address width to use: 3,4 or 5 */ void setAddressWidth(uint8_t a_width); /** * Set the number and delay of retries upon failed submit * * @param delay How long to wait between each retry, in multiples of 250us, * max is 15. 0 means 250us, 15 means 4000us. * @param count How many retries before giving up, max 15 */ void setRetries(uint8_t delay, uint8_t count); /** * Set RF communication channel * * @param channel Which RF channel to communicate on, 0-125 */ void setChannel(uint8_t channel); /** * Get RF communication channel * * @return The currently configured RF Channel */ uint8_t getChannel(void); /** * Set Static Payload Size * * This implementation uses a pre-stablished fixed payload size for all * transmissions. If this method is never called, the driver will always * transmit the maximum payload size (32 bytes), no matter how much * was sent to write(). * * @todo Implement variable-sized payloads feature * * @param size The number of bytes in the payload */ void setPayloadSize(uint8_t size); /** * Get Static Payload Size * * @see setPayloadSize() * * @return The number of bytes in the payload */ uint8_t getPayloadSize(void); /** * Get Dynamic Payload Size * * For dynamic payloads, this pulls the size of the payload off * the chip * * @note Corrupt packets are now detected and flushed per the * manufacturer. * @code * if(radio.available()){ * if(radio.getDynamicPayloadSize() < 1){ * // Corrupt payload has been flushed * return; * } * radio.read(&data,sizeof(data)); * } * @endcode * * @return Payload length of last-received dynamic payload */ uint8_t getDynamicPayloadSize(void); /** * Enable custom payloads on the acknowledge packets * * Ack payloads are a handy way to return data back to senders without * manually changing the radio modes on both units. * * @note Ack payloads are dynamic payloads. This only works on pipes 0&1 by default. Call * enableDynamicPayloads() to enable on all pipes. */ void enableAckPayload(void); /** * Enable dynamically-sized payloads * * This way you don't always have to send large packets just to send them * once in a while. This enables dynamic payloads on ALL pipes. * */ void enableDynamicPayloads(void); /** * Disable dynamically-sized payloads * * This disables dynamic payloads on ALL pipes. Since Ack Payloads * requires Dynamic Payloads, Ack Payloads are also disabled. * If dynamic payloads are later re-enabled and ack payloads are desired * then enableAckPayload() must be called again as well. * */ void disableDynamicPayloads(void); /** * Enable dynamic ACKs (single write multicast or unicast) for chosen messages * * @note To enable full multicast or per-pipe multicast, use setAutoAck() * * @warning This MUST be called prior to attempting single write NOACK calls * @code * radio.enableDynamicAck(); * radio.write(&data,32,1); // Sends a payload with no acknowledgement requested * radio.write(&data,32,0); // Sends a payload using auto-retry/autoACK * @endcode */ void enableDynamicAck(); /** * Determine whether the hardware is an nRF24L01+ or not. * * @return true if the hardware is nRF24L01+ (or compatible) and false * if its not. */ bool isPVariant(void); /** * Enable or disable auto-acknowlede packets * * This is enabled by default, so it's only needed if you want to turn * it off for some reason. * * @param enable Whether to enable (true) or disable (false) auto-acks */ void setAutoAck(bool enable); /** * Enable or disable auto-acknowlede packets on a per pipeline basis. * * AA is enabled by default, so it's only needed if you want to turn * it off/on for some reason on a per pipeline basis. * * @param pipe Which pipeline to modify * @param enable Whether to enable (true) or disable (false) auto-acks */ void setAutoAck(uint8_t pipe, bool enable); /** * Set Power Amplifier (PA) level to one of four levels: * RF24_PA_MIN, RF24_PA_LOW, RF24_PA_HIGH and RF24_PA_MAX * * The power levels correspond to the following output levels respectively: * NRF24L01: -18dBm, -12dBm,-6dBM, and 0dBm, lnaEnable affects modules with LNA * * SI24R1: -6dBm, 0dBm, 3dBm and 7dBm with lnaEnable = 1 * -12dBm,-4dBm, 1dBm and 4dBm with lnaEnable = 0 * * @param level Desired PA level. * @param lnaEnable En/Disable LNA Gain */ void setPALevel(uint8_t level, bool lnaEnable = 1); /** * Fetches the current PA level. * * NRF24L01: -18dBm, -12dBm, -6dBm and 0dBm * SI24R1: -6dBm, 0dBm, 3dBm, 7dBm * * @return Returns values 0 to 3 representing the PA Level. */ uint8_t getPALevel(void); /** * Returns automatic retransmission count (ARC_CNT) * * Value resets with each new transmission. Allows roughly estimating signal strength. * * @return Returns values from 0 to 15. */ uint8_t getARC(void); /** * Set the transmission data rate * * @warning setting RF24_250KBPS will fail for non-plus units * * @param speed RF24_250KBPS for 250kbs, RF24_1MBPS for 1Mbps, or RF24_2MBPS for 2Mbps * @return true if the change was successful */ bool setDataRate(rf24_datarate_e speed); /** * Fetches the transmission data rate * * @return Returns the hardware's currently configured datarate. The value * is one of 250kbs, RF24_1MBPS for 1Mbps, or RF24_2MBPS, as defined in the * rf24_datarate_e enum. */ rf24_datarate_e getDataRate(void); /** * Set the CRC length *
CRC checking cannot be disabled if auto-ack is enabled * @param length RF24_CRC_8 for 8-bit or RF24_CRC_16 for 16-bit */ void setCRCLength(rf24_crclength_e length); /** * Get the CRC length *
CRC checking cannot be disabled if auto-ack is enabled * @return RF24_CRC_DISABLED if disabled or RF24_CRC_8 for 8-bit or RF24_CRC_16 for 16-bit */ rf24_crclength_e getCRCLength(void); /** * Disable CRC validation * * @warning CRC cannot be disabled if auto-ack/ESB is enabled. */ void disableCRC(void); /** * The radio will generate interrupt signals when a transmission is complete, * a transmission fails, or a payload is received. This allows users to mask * those interrupts to prevent them from generating a signal on the interrupt * pin. Interrupts are enabled on the radio chip by default. * * @code * Mask all interrupts except the receive interrupt: * * radio.maskIRQ(1,1,0); * @endcode * * @param tx_ok Mask transmission complete interrupts * @param tx_fail Mask transmit failure interrupts * @param rx_ready Mask payload received interrupts */ void maskIRQ(bool tx_ok, bool tx_fail, bool rx_ready); /** * * The driver will delay for this duration when stopListening() is called * * When responding to payloads, faster devices like ARM(RPi) are much faster than Arduino: * 1. Arduino sends data to RPi, switches to RX mode * 2. The RPi receives the data, switches to TX mode and sends before the Arduino radio is in RX mode * 3. If AutoACK is disabled, this can be set as low as 0. If AA/ESB enabled, set to 100uS minimum on RPi * * @warning If set to 0, ensure 130uS delay after stopListening() and before any sends */ uint32_t txDelay; /** * * On all devices but Linux and ATTiny, a small delay is added to the CSN toggling function * * This is intended to minimise the speed of SPI polling due to radio commands * * If using interrupts or timed requests, this can be set to 0 Default:5 */ uint32_t csDelay; /** * Transmission of constant carrier wave with defined frequency and output power * * @param level Output power to use * @param channel The channel to use */ void startConstCarrier(rf24_pa_dbm_e level, uint8_t channel); /** * Stop transmission of constant wave and reset PLL and CONT registers */ void stopConstCarrier(void); /**@}*/ /** * @name Deprecated * * Methods provided for backwards compabibility. */ /**@{*/ /** * Open a pipe for reading * @note For compatibility with old code only, see new function * * @warning Pipes 1-5 should share the first 32 bits. * Only the least significant byte should be unique, e.g. * @code * openReadingPipe(1,0xF0F0F0F0AA); * openReadingPipe(2,0xF0F0F0F066); * @endcode * * @warning Pipe 0 is also used by the writing pipe so should typically be avoided as a reading pipe.
* If used, the reading pipe 0 address needs to be restored at avery call to startListening(), and the address
* is ONLY restored if the LSB is a non-zero value.
See http://maniacalbits.blogspot.com/2013/04/rf24-addressing-nrf24l01-radios-require.html * * @param number Which pipe# to open, 0-5. * @param address The 40-bit address of the pipe to open. */ void openReadingPipe(uint8_t number, uint64_t address); /** * Open a pipe for writing * @note For compatibility with old code only, see new function * * Addresses are 40-bit hex values, e.g.: * * @code * openWritingPipe(0xF0F0F0F0F0); * @endcode * * @param address The 40-bit address of the pipe to open. */ void openWritingPipe(uint64_t address); /** * Empty the receive buffer * * @return Current value of status register */ uint8_t flush_rx(void); private: /** * @name Low-level internal interface. * * Protected methods that address the chip directly. Regular users cannot * ever call these. They are documented for completeness and for developers who * may want to extend this class. */ /**@{*/ /** * Set chip select pin * * Running SPI bus at PI_CLOCK_DIV2 so we don't waste time transferring data * and best of all, we make use of the radio's FIFO buffers. A lower speed * means we're less likely to effectively leverage our FIFOs and pay a higher * AVR runtime cost as toll. * * @param mode HIGH to take this unit off the SPI bus, LOW to put it on */ void csn(bool mode); /** * Set chip enable * * @param level HIGH to actively begin transmission or LOW to put in standby. Please see data sheet * for a much more detailed description of this pin. */ void ce(bool level); /** * Read a chunk of data in from a register * * @param reg Which register. Use constants from nRF24L01.h * @param buf Where to put the data * @param len How many bytes of data to transfer * @return Current value of status register */ uint8_t read_register(uint8_t reg, uint8_t* buf, uint8_t len); /** * Read single byte from a register * * @param reg Which register. Use constants from nRF24L01.h * @return Current value of register @p reg */ uint8_t read_register(uint8_t reg); /** * Write a chunk of data to a register * * @param reg Which register. Use constants from nRF24L01.h * @param buf Where to get the data * @param len How many bytes of data to transfer * @return Current value of status register */ uint8_t write_register(uint8_t reg, const uint8_t* buf, uint8_t len); /** * Write a single byte to a register * * @param reg Which register. Use constants from nRF24L01.h * @param value The new value to write * @return Current value of status register */ uint8_t write_register(uint8_t reg, uint8_t value); /** * Write the transmit payload * * The size of data written is the fixed payload size, see getPayloadSize() * * @param buf Where to get the data * @param len Number of bytes to be sent * @return Current value of status register */ uint8_t write_payload(const void* buf, uint8_t len, const uint8_t writeType); /** * Read the receive payload * * The size of data read is the fixed payload size, see getPayloadSize() * * @param buf Where to put the data * @param len Maximum number of bytes to read * @return Current value of status register */ uint8_t read_payload(void* buf, uint8_t len); /** * Retrieve the current status of the chip * * @return Current value of status register */ uint8_t get_status(void); #if !defined (MINIMAL) /** * Decode and print the given status to stdout * * @param status Status value to print * * @warning Does nothing if stdout is not defined. See fdevopen in stdio.h */ void print_status(uint8_t status); /** * Decode and print the given 'observe_tx' value to stdout * * @param value The observe_tx value to print * * @warning Does nothing if stdout is not defined. See fdevopen in stdio.h */ void print_observe_tx(uint8_t value); /** * Print the name and value of an 8-bit register to stdout * * Optionally it can print some quantity of successive * registers on the same line. This is useful for printing a group * of related registers on one line. * * @param name Name of the register * @param reg Which register. Use constants from nRF24L01.h * @param qty How many successive registers to print */ void print_byte_register(const char* name, uint8_t reg, uint8_t qty = 1); /** * Print the name and value of a 40-bit address register to stdout * * Optionally it can print some quantity of successive * registers on the same line. This is useful for printing a group * of related registers on one line. * * @param name Name of the register * @param reg Which register. Use constants from nRF24L01.h * @param qty How many successive registers to print */ void print_address_register(const char* name, uint8_t reg, uint8_t qty = 1); #endif /** * Turn on or off the special features of the chip * * The chip has certain 'features' which are only available when the 'features' * are enabled. See the datasheet for details. */ void toggle_features(void); /** * Built in spi transfer function to simplify repeating code repeating code */ uint8_t spiTrans(uint8_t cmd); #if defined (FAILURE_HANDLING) || defined (RF24_LINUX) void errNotify(void); #endif /**@}*/ }; /** * @example GettingStarted.ino * For Arduino
* Updated: TMRh20 2014
* * This is an example of how to use the RF24 class to communicate on a basic level. Configure and write this sketch to two * different nodes. Put one of the nodes into 'transmit' mode by connecting with the serial monitor and
* sending a 'T'. The ping node sends the current time to the pong node, which responds by sending the value * back. The ping node can then see how long the whole cycle took.
* @note For a more efficient call-response scenario see the GettingStarted_CallResponse.ino example. * @note When switching between sketches, the radio may need to be powered down to clear settings that are not "un-set" otherwise */ /** * @example gettingstarted.cpp * For Linux
* Updated: TMRh20 2014
* * This is an example of how to use the RF24 class to communicate on a basic level. Configure and write this sketch to two * different nodes. Put one of the nodes into 'transmit' mode by connecting with the serial monitor and
* sending a 'T'. The ping node sends the current time to the pong node, which responds by sending the value * back. The ping node can then see how long the whole cycle took.
* @note For a more efficient call-response scenario see the GettingStarted_CallResponse.ino example. */ /** * @example GettingStarted_CallResponse.ino * For Arduino
* New: TMRh20 2014
* * This example continues to make use of all the normal functionality of the radios including * the auto-ack and auto-retry features, but allows ack-payloads to be written optionlly as well.
* This allows very fast call-response communication, with the responding radio never having to * switch out of Primary Receiver mode to send back a payload, but having the option to switch to
* primary transmitter if wanting to initiate communication instead of respond to a commmunication. */ /** * @example gettingstarted_call_response.cpp * For Linux
* New: TMRh20 2014
* * This example continues to make use of all the normal functionality of the radios including * the auto-ack and auto-retry features, but allows ack-payloads to be written optionlly as well.
* This allows very fast call-response communication, with the responding radio never having to * switch out of Primary Receiver mode to send back a payload, but having the option to switch to
* primary transmitter if wanting to initiate communication instead of respond to a commmunication. */ /** * @example GettingStarted_HandlingData.ino * Dec 2014 - TMRh20
* * This example demonstrates how to send multiple variables in a single payload and work with data. As usual, it is * generally important to include an incrementing value like millis() in the payloads to prevent errors. */ /** * @example GettingStarted_HandlingFailures.ino * * This example demonstrates the basic getting started functionality, but with failure handling for the radio chip. * Addresses random radio failures etc, potentially due to loose wiring on breadboards etc. */ /** * @example Transfer.ino * For Arduino
* This example demonstrates half-rate transfer using the FIFO buffers
* * It is an example of how to use the RF24 class. Write this sketch to two * different nodes. Put one of the nodes into 'transmit' mode by connecting
* with the serial monitor and sending a 'T'. The data transfer will begin, * with the receiver displaying the payload count. (32Byte Payloads)
*/ /** * @example transfer.cpp * For Linux
* This example demonstrates half-rate transfer using the FIFO buffers
* * It is an example of how to use the RF24 class. Write this sketch to two * different nodes. Put one of the nodes into 'transmit' mode by connecting
* with the serial monitor and sending a 'T'. The data transfer will begin, * with the receiver displaying the payload count. (32Byte Payloads)
*/ /** * @example TransferTimeouts.ino * New: TMRh20
* This example demonstrates the use of and extended timeout period and * auto-retries/auto-reUse to increase reliability in noisy or low signal scenarios.
* * Write this sketch to two different nodes. Put one of the nodes into 'transmit' * mode by connecting with the serial monitor and sending a 'T'. The data
* transfer will begin, with the receiver displaying the payload count and the * data transfer rate. */ /** * @example starping.pde * * This sketch is a more complex example of using the RF24 library for Arduino. * Deploy this on up to six nodes. Set one as the 'pong receiver' by tying the * role_pin low, and the others will be 'ping transmit' units. The ping units * unit will send out the value of millis() once a second. The pong unit will * respond back with a copy of the value. Each ping unit can get that response * back, and determine how long the whole cycle took. * * This example requires a bit more complexity to determine which unit is which. * The pong receiver is identified by having its role_pin tied to ground. * The ping senders are further differentiated by a byte in eeprom. */ /** * @example pingpair_ack.ino * Update: TMRh20
* This example continues to make use of all the normal functionality of the radios including * the auto-ack and auto-retry features, but allows ack-payloads to be written optionlly as well.
* This allows very fast call-response communication, with the responding radio never having to * switch out of Primary Receiver mode to send back a payload, but having the option to if wanting
* to initiate communication instead of respond to a commmunication. */ /** * @example pingpair_irq.ino * Update: TMRh20
* This is an example of how to user interrupts to interact with the radio, and a demonstration * of how to use them to sleep when receiving, and not miss any payloads.
* The pingpair_sleepy example expands on sleep functionality with a timed sleep option for the transmitter. * Sleep functionality is built directly into my fork of the RF24Network library
*/ /** * @example pingpair_irq_simple.ino * Dec 2014 - TMRh20
* This is an example of how to user interrupts to interact with the radio, with bidirectional communication. */ /** * @example pingpair_sleepy.ino * Update: TMRh20
* This is an example of how to use the RF24 class to create a battery- * efficient system. It is just like the GettingStarted_CallResponse example, but the
* ping node powers down the radio and sleeps the MCU after every * ping/pong cycle, and the receiver sleeps between payloads.
*/ /** * @example rf24ping85.ino * New: Contributed by https://github.com/tong67
* This is an example of how to use the RF24 class to communicate with ATtiny85 and other node.
*/ /** * @example timingSearch3pin.ino * New: Contributed by https://github.com/tong67
* This is an example of how to determine the correct timing for ATtiny when using only 3-pins */ /** * @example pingpair_dyn.ino * * This is an example of how to use payloads of a varying (dynamic) size on Arduino. */ /** * @example pingpair_dyn.cpp * * This is an example of how to use payloads of a varying (dynamic) size on Linux. */ /** * @example pingpair_dyn.py * * This is a python example for RPi of how to use payloads of a varying (dynamic) size. */ /** * @example scanner.ino * * Example to detect interference on the various channels available. * This is a good diagnostic tool to check whether you're picking a * good channel for your application. * * Inspired by cpixip. * See http://arduino.cc/forum/index.php/topic,54795.0.html */ /** * @mainpage Optimized High Speed Driver for nRF24L01(+) 2.4GHz Wireless Transceiver * * @section Goals Design Goals * * This library fork is designed to be... * @li More compliant with the manufacturer specified operation of the chip, while allowing advanced users * to work outside the recommended operation. * @li Utilize the capabilities of the radio to their full potential via Arduino * @li More reliable, responsive, bug-free and feature rich * @li Easy for beginners to use, with well documented examples and features * @li Consumed with a public interface that's similar to other Arduino standard libraries * * @section News News * * **Aug 2020**
* v1.3.8 * - Introduces change that mainly reduces the time required to call startListening(), powerUp(), and powerDown() * - Affects speed of switching from TX->RX. Users might consider starting updates of slower devices with this
* release to prevent missed packets when similar changes are introduced, affecting switching from RX->TX * - Clean up begin() function (reduce program size) * * v1.3.7 * - Bug fix for writeFast() function affecting RF24 stack (all RF24 libraries) * - Unify Arduino & Linux constructor. Accept SPI speed in Hz as optional parameter * - Removal of BCM2835 SPI speed constants due to removal from BCM library * - Update to latest BCM2835 driver * - Bug fix for RPi millis() code * - Added Constant Carrier Wave functionality & added to scanner example * - Modify setPALevel() to allow setting LNA gain via optional parameter * - Cleanup of warnings, errors and old files * * **March-July 2020** * - Fixes for SPI_HAS_TRANSACTION detection (Affecting many devices) * - Add ability to configure SPI speed properly in Linux constructor * - Support multiple instances of SPIDEV on Linux * - Minor fixes & changes * * * * @section Useful Useful References * * * @li RF24 Class Documentation * @li Support & Configuration * @li Source Code * @li nrf24L01 v2.0 Datasheet * @li nrf24L01+ v1.0 Datasheet * * **Additional Information and Add-ons** * * @li RF24Network: OSI Network Layer for multi-device communication. Create a home sensor network. * @li RF24Mesh: Dynamic Mesh Layer for RF24Network * @li RF24Ethernet: TCP/IP Radio Mesh Networking (shares Arduino Ethernet API) * @li RF24Audio: Realtime Wireless Audio streaming * @li My Blog: RF24 Optimization Overview * @li My Blog: RPi/Linux w/RF24Gateway * @li All TMRh20 Documentation Main Page * * **More Information** * * @li Project Blog: TMRh20.blogspot.com * @li Maniacal Bits Blog * @li Original Maniacbug RF24Network Blog Post * @li ManiacBug on GitHub (Original Library Author) * @li MySensors.org (User friendly sensor networks/IoT) * *
* * @section Platform_Support Platform Support Pages * * @li Arduino (Uno, Nano, Mega, Due, Galileo, etc) * @li ATTiny * @li Linux Installation( Linux/RPi General , MRAA supported boards ( Galileo, Edison, etc), LittleWire) * @li Cross-compilation for linux devices * @li Python wrapper available for Linux devices * *
* **General µC Pin layout** (See the individual board support pages for more info) * * The table below shows how to connect the the pins of the NRF24L01(+) to different boards. * CE and CSN are configurable. * * | PIN | NRF24L01 | Arduino UNO | ATtiny25/45/85 [0] | ATtiny44/84 [1] | LittleWire [2] | RPI | RPi -P1 Connector | * |-----|----------|-------------|--------------------|-----------------|-------------------------|------------|-------------------| * | 1 | GND | GND | pin 4 | pin 14 | GND | rpi-gnd | (25) | * | 2 | VCC | 3.3V | pin 8 | pin 1 | regulator 3.3V required | rpi-3v3 | (17) | * | 3 | CE | digIO 7 | pin 2 | pin 12 | pin to 3.3V | rpi-gpio22 | (15) | * | 4 | CSN | digIO 8 | pin 3 | pin 11 | RESET | rpi-gpio8 | (24) | * | 5 | SCK | digIO 13 | pin 7 | pin 9 | SCK | rpi-sckl | (23) | * | 6 | MOSI | digIO 11 | pin 6 | pin 7 | MOSI | rpi-mosi | (19) | * | 7 | MISO | digIO 12 | pin 5 | pin 8 | MISO | rpi-miso | (21) | * | 8 | IRQ | - | - | - | - | - | - | * * @li [0] https://learn.sparkfun.com/tutorials/tiny-avr-programmer-hookup-guide/attiny85-use-hints * @li [1] http://highlowtech.org/?p=1695 * @li [2] http://littlewire.cc/ *


* * * * * @page Arduino Arduino * * RF24 is fully compatible with Arduino boards
* See http://www.arduino.cc/en/Reference/Board and http://arduino.cc/en/Reference/SPI for more information * * RF24 makes use of the standard hardware SPI pins (MISO,MOSI,SCK) and requires two additional pins, to control * the chip-select and chip-enable functions.
* These pins must be chosen and designated by the user, in RF24 radio(ce_pin,cs_pin); and can use any * available pins. * *
* @section Alternate_SPI Alternate SPI Support * * RF24 supports alternate SPI methods, in case the standard hardware SPI pins are otherwise unavailable. * *
* **Software Driven SPI** * * Software driven SPI is provided by the DigitalIO library * * Setup:
* 1. Install the digitalIO library
* 2. Open RF24_config.h in a text editor. Uncomment the line @code #define SOFTSPI @endcode or add the build flag/option @code -DSOFTSPI @endcode * 3. In your sketch, add * @code * #include DigitalIO.h * @endcode * * @note Note: Pins are listed as follows and can be modified by editing the RF24_config.h file
* * #define SOFT_SPI_MISO_PIN 16 * #define SOFT_SPI_MOSI_PIN 15 * #define SOFT_SPI_SCK_PIN 14 * Or add the build flag/option * * -DSOFT_SPI_MISO_PIN=16 -DSOFT_SPI_MOSI_PIN=15 -DSOFT_SPI_SCK_PIN=14 * *
* **Alternate Hardware (UART) Driven SPI** * * The Serial Port (UART) on Arduino can also function in SPI mode, and can double-buffer data, while the * default SPI hardware cannot. * * The SPI_UART library is available at https://github.com/TMRh20/Sketches/tree/master/SPI_UART * * Enabling: * 1. Install the SPI_UART library * 2. Edit RF24_config.h and uncomment `#define SPI_UART` * 3. In your sketch, add @code #include @endcode * * SPI_UART SPI Pin Connections: * | NRF |Arduino Uno Pin| * |-----|---------------| * | MOSI| TX(0) | * | MISO| RX(1) | * | SCK | XCK(4) | * | CE | User Specified| * | CSN | User Specified| * * * @note SPI_UART on Mega boards requires soldering to an unused pin on the chip.
See * https://github.com/TMRh20/RF24/issues/24 for more information on SPI_UART. * * @page ATTiny ATTiny * * ATTiny support is built into the library, so users are not required to include SPI.h in their sketches
* See the included rf24ping85 example for pin info and usage * * Some versions of Arduino IDE may require a patch to allow use of the full program space on ATTiny
* See https://github.com/TCWORLD/ATTinyCore/tree/master/PCREL%20Patch%20for%20GCC for ATTiny patch * * ATTiny board support initially added from https://github.com/jscrane/RF24 * * @section Hardware Hardware Configuration * By tong67 ( https://github.com/tong67 ) * * **ATtiny25/45/85 Pin map with CE_PIN 3 and CSN_PIN 4** * @code * +-\/-+ * NC PB5 1|o |8 Vcc --- nRF24L01 VCC, pin2 --- LED --- 5V * nRF24L01 CE, pin3 --- PB3 2| |7 PB2 --- nRF24L01 SCK, pin5 * nRF24L01 CSN, pin4 --- PB4 3| |6 PB1 --- nRF24L01 MOSI, pin6 * nRF24L01 GND, pin1 --- GND 4| |5 PB0 --- nRF24L01 MISO, pin7 * +----+ * @endcode * *
* **ATtiny25/45/85 Pin map with CE_PIN 3 and CSN_PIN 3** => PB3 and PB4 are free to use for application
* Circuit idea from http://nerdralph.blogspot.ca/2014/01/nrf24l01-control-with-3-attiny85-pins.html
* Original RC combination was 1K/100nF. 22K/10nF combination worked better.
* For best settletime delay value in RF24::csn() the timingSearch3pin.ino sketch can be used.
* This configuration is enabled when CE_PIN and CSN_PIN are equal, e.g. both 3
* Because CE is always high the power consumption is higher than for 5 pins solution
* @code * ^^ * +-\/-+ nRF24L01 CE, pin3 ------| // * PB5 1|o |8 Vcc --- nRF24L01 VCC, pin2 ------x----------x--|<|-- 5V * NC PB3 2| |7 PB2 --- nRF24L01 SCK, pin5 --|<|---x-[22k]--| LED * NC PB4 3| |6 PB1 --- nRF24L01 MOSI, pin6 1n4148 | * nRF24L01 GND, pin1 -x- GND 4| |5 PB0 --- nRF24L01 MISO, pin7 | * | +----+ | * |-----------------------------------------------||----x-- nRF24L01 CSN, pin4 * 10nF * @endcode * *
* **ATtiny24/44/84 Pin map with CE_PIN 8 and CSN_PIN 7**
* Schematic provided and successfully tested by Carmine Pastore (https://github.com/Carminepz)
* @code * +-\/-+ * nRF24L01 VCC, pin2 --- VCC 1|o |14 GND --- nRF24L01 GND, pin1 * PB0 2| |13 AREF * PB1 3| |12 PA1 * PB3 4| |11 PA2 --- nRF24L01 CE, pin3 * PB2 5| |10 PA3 --- nRF24L01 CSN, pin4 * PA7 6| |9 PA4 --- nRF24L01 SCK, pin5 * nRF24L01 MISO, pin7 --- PA6 7| |8 PA5 --- nRF24L01 MOSI, pin6 * +----+ * @endcode * *
* **ATtiny2313/4313 Pin map with CE_PIN 12 and CSN_PIN 13**
* @code * +-\/-+ * PA2 1|o |20 VCC --- nRF24L01 VCC, pin2 * PD0 2| |19 PB7 --- nRF24L01 SCK, pin5 * PD1 3| |18 PB6 --- nRF24L01 MOSI, pin6 * PA1 4| |17 PB5 --- nRF24L01 MISO, pin7 * PA0 5| |16 PB4 --- nRF24L01 CSN, pin4 * PD2 6| |15 PB3 --- nRF24L01 CE, pin3 * PD3 7| |14 PB2 * PD4 8| |13 PB1 * PD5 9| |12 PB0 * nRF24L01 GND, pin1 --- GND 10| |11 PD6 * +----+ * @endcode * *


* * * * * * * @page Linux Linux Installation * * Generic Linux devices are supported via SPIDEV, MRAA, RPi native via BCM2835, or using LittleWire. * * @note The SPIDEV option should work with most Linux systems supporting spi userspace device.
* *
* @section AutoInstall Automated Install *(**Designed & Tested on RPi** - Defaults to SPIDEV on devices supporting it) * * * 1. Install prerequisites if there are any (MRAA, LittleWire libraries, setup SPI device etc) * 2. Download the install.sh file from http://tmrh20.github.io/RF24Installer/RPi/install.sh * @code wget http://tmrh20.github.io/RF24Installer/RPi/install.sh @endcode * 3. Make it executable * @code chmod +x install.sh @endcode * 4. Run it and choose your options * @code ./install.sh @endcode * 5. Run an example from one of the libraries * @code * cd rf24libs/RF24/examples_linux * @endcode * Edit the gettingstarted example, to set your pin configuration * @code nano gettingstarted.cpp * make * sudo ./gettingstarted * @endcode * *
* @section ManInstall Manual Install * 1. Install prerequisites if there are any (MRAA, LittleWire libraries, setup SPI device etc) * @note See the MRAA documentation for more info on installing MRAA
* 2. Make a directory to contain the RF24 and possibly RF24Network lib and enter it * @code * mkdir ~/rf24libs * cd ~/rf24libs * @endcode * 3. Clone the RF24 repo * @code git clone https://github.com/tmrh20/RF24.git RF24 @endcode * 4. Change to the new RF24 directory * @code cd RF24 @endcode * 5. Configure build environment using @code ./configure @endcode script. It auto detectes device and build environment. For overriding autodetections, use command-line switches, see @code ./configure --help @endcode for description. * 6. Build the library, and run an example file * @code make; sudo make install @endcode * @code * cd examples_linux * @endcode * Edit the gettingstarted example, to set your pin configuration * @code nano gettingstarted.cpp * make * sudo ./gettingstarted * @endcode * * Build using **SPIDEV** * * 1. Make sure that spi device support is enabled and /dev/spidev\.\ is present * 2. Manual Install using SPIDEV: * @code * ./configure --driver=SPIDEV * make; sudo make install * @endcode * 3. See the gettingstarted example for an example of pin configuration *

* * @page MRAA MRAA * * MRAA is a Low Level Skeleton Library for Communication on GNU/Linux platforms
* See http://iotdk.intel.com/docs/master/mraa/index.html for more information * * RF24 supports all MRAA supported platforms, but might not be tested on each individual platform due to the wide range of hardware support:
* Report an RF24 bug or issue * * @section Setup Setup and installation * * Build using the **MRAA** library from http://iotdk.intel.com/docs/master/mraa/index.html
* MRAA is not included. * * 1. Install, and build MRAA * @code * git clone https://github.com/intel-iot-devkit/mraa.git * cd mraa * mkdir build * cd build * cmake .. -DBUILDSWIGNODE=OFF * sudo make install * @endcode * * 2. Complete the install
* @code nano /etc/ld.so.conf @endcode * Add the line @code /usr/local/lib/arm-linux-gnueabihf @endcode * Run @code sudo ldconfig @endcode * * 3. Install RF24, using MRAA * See http://tmrh20.github.io/RF24/Linux.html * * *


* * * * * @page RPi Linux General/Raspberry Pi * * RF24 supports a variety of Linux based devices via various drivers. Some boards like RPi can utilize multiple methods * to drive the GPIO and SPI functionality. * * * @section PreConfig Potential PreConfiguration * * If SPI is not already enabled, load it on boot: * @code sudo raspi-config @endcode * A. Update the tool via the menu as required
* B. Select **Advanced** and **enable the SPI kernel module**
* C. Update other software and libraries * @code sudo apt-get update @endcode * @code sudo apt-get upgrade @endcode *
* * @section Build Build Options * The default build on Raspberry Pi utilizes the included **BCM2835** driver from http://www.airspayce.com/mikem/bcm2835 * 1. See the Linux section for automated installation * 2. Manual install:
* @code make; sudo make install @endcode * * *
* @section Pins Connections and Pin Configuration * * * Using pin 15/GPIO 22 for CE, pin 24/GPIO8 (CE0) for CSN * * Can use any available SPI BUS for CSN.
* In general, use @code RF24 radio(, *10+); @endcode for proper constructor to * address correct spi device at /dev/spidev\.\ *
* Choose any GPIO output pin for radio CE pin. * * **General:** * @code RF24 radio(22,0); @endcode * * **MRAA Constructor:** * * @code RF24 radio(15,0); @endcode * * See http://iotdk.intel.com/docs/master/mraa/rasppi.html *

* **SPI_DEV Constructor** * * @code RF24 radio(22,0); @endcode * * * https://www.raspberrypi.org/documentation/usage/gpio/ * * **Pins:** * * | PIN | NRF24L01 | RPI | RPi -P1 Connector | * |-----|----------|------------|-------------------| * | 1 | GND | rpi-gnd | (25) | * | 2 | VCC | rpi-3v3 | (17) | * | 3 | CE | rpi-gpio22 | (15) | * | 4 | CSN | rpi-gpio8 | (24) | * | 5 | SCK | rpi-sckl | (23) | * | 6 | MOSI | rpi-mosi | (19) | * | 7 | MISO | rpi-miso | (21) | * | 8 | IRQ | - | - | * * * * *

**************** * * Based on the arduino lib from J. Coliz
* the library was berryfied by Purinda Gunasekara
* then forked from github stanleyseow/RF24 to https://github.com/jscrane/RF24-rpi
* Network lib also based on https://github.com/farconada/RF24Network * * * * *


* * * * @page Python Python Wrapper (by https://github.com/mz-fuzzy) * * @section Prerequisites Prerequisites * * Python2: * * @code sudo apt-get install python-dev libboost-python-dev python-setuptools python-rpi.gpio @endcode * * Python3: * * @code sudo apt-get install python3-dev libboost-python-dev python3-setuptools python3-rpi.gpio @endcode * * RF24: * * The RF24 lib needs to be built in C++ & installed for the python wrapper to wrap it
* See
Linux Installation and Linux/RPi General *

* @section Install Installation: * 1. For python3 in Raspbian, it's needed to manually link python boost library, like this: * @code sudo ln -s $(ls /usr/lib/arm-linux-gnueabihf/libboost_python3-py3*.so | tail -1) /usr/lib/arm-linux-gnueabihf/libboost_python3.so @endcode * * 2. Build the library. From the rf24libs/RF24/pyRF24 directory: * @code ./setup.py build @endcode or @code python3 setup.py build @endcode * @note Build takes several minutes on arm-based machines. Machines with RAM <1GB may need to increase amount of swap for build. * * 3. Install the library * @code sudo ./setup.py install @endcode or @code sudo python3 setup.py install @endcode * See the additional Platform Support pages for information on connecting your hardware
* See the included example for usage information. * * 5. Running the Example:
* Edit the pingpair_dyn.py example to configure the appropriate pins per the above documentation: * @code nano pingpair_dyn.py @endcode * Configure another device, Arduino or RPi with the pingpair_dyn example
* Run the example * @code sudo ./pingpair_dyn.py @endcode or @code sudo python3 pingpair_dyn.py @endcode * *


* * @page CrossCompile Linux cross-compilation * * RF24 library supports cross-compilation. Advantages of cross-compilation: * - development tools don't have to be installed on target machine * - resources of target machine don't have to be sufficient for compilation * - compilation time can be reduced for large projects * * Following prerequisites need to be assured: * - ssh passwordless access to target machine (https://linuxconfig.org/passwordless-ssh) * - sudo of a remote user without password (http://askubuntu.com/questions/334318/sudoers-file-enable-nopasswd-for-user-all-commands) * - cross-compilation toolchain for your target machine; for RPi * @code git clone https://github.com/raspberrypi/tools rpi_tools @endcode * and cross-compilation tools must be in PATH, for example * @code export PATH=$PATH:/your/dir/rpi-tools/arm-bcm2708/gcc-linaro-arm-linux-gnueabihf-raspbian-x64/bin @endcode * * @section CxSteps Cross compilation steps: * 1. clone RF24 to a machine for cross-compilation * @code * git clone https://github.com/TMRh20/RF24 * cd RF24 * @endcode * 2. configure for cross compilation * @code ./configure --remote=pi@target_linux_host @endcode * eventually * @code ./configure --remote=pi@target_linux_host --driver= @endcode * 3. build * @code make @endcode * 4. (opt) install library to cross-compilation machine into cross-exvironment - important for compilation of examples * @code sudo make install @endcode * 5. upload library to target machine * @code make upload @endcode * 6. (opt) compile examples * @code * cd examples_linux * make * @endcode * 7. (opt) upload examples to target machine * @code make upload @endcode * * @section CxStepsPython Cross comilation steps for python wrapper * * Prerequisites: * - Python setuptools must be installed on both target and cross-compilation machines * @code sudo pip install setuptools @endcode * or * @code sudo apt-get install python-setuptools @endcode * * Installation steps: * 1. Assure having libboost-python-dev library in your cross-compilation environment. Alternatively, you can install it into your target machine and copy /usr and /lib directories to the cross-compilation machine. * For example * @code * mkdir -p rpi_root && rsync -a pi@target_linux_host:/usr :/lib rpi_root * export CFLAGS="--sysroot=/your/dir/rpi_root -I/your/dir/rpi_root/usr/include/python2.7/" * @endcode * * 2. Build the python wrapper * @code * cd pyRF24 * ./setup.py build --compiler=crossunix * @endcode * * 3. Make the egg package * @code ./setup.py bdist_egg --plat-name=cross @endcode * `dist/RF24--cross.egg` should be created. * * 4. Upload it to the target machine and install there: * @code * scp dist/RF24-*-cross.egg pi@target_linux_host: * ssh pi@target_linux_host 'sudo easy_install RF24-*-cross.egg' * @endcode * *


* * @page ATXMEGA ATXMEGA * * The RF24 driver can be build as a static library with Atmel Studio 7 in order to be included as any other library in another program for the XMEGA family. * * Currently only the ATXMEGA D3 family is implemented. * * @section Preparation * * Create an empty GCC Static Library project in AS7.
* As not all files are required, copy the following directory structure in the project: * * @code * utility\ * ATXMegaD3\ * compatibility.c * compatibility.h * gpio.cpp * gpio.h * gpio_helper.c * gpio_helper.h * includes.h * RF24_arch_config.h * spi.cpp * spi.h * nRF24L01.h * printf.h * RF24.cpp * RF24.h * RF24_config.h * @endcode * * @section Usage * * Add the library to your project!
* In the file where the **main()** is put the following in order to update the millisecond functionality: * * @code * ISR(TCE0_OVF_vect) * { * update_milisec(); * } * @endcode * * Declare the rf24 radio with **RF24 radio(XMEGA_PORTC_PIN3, XMEGA_SPI_PORT_C);** * * First parameter is the CE pin which can be any available pin on the uC. * * Second parameter is the CS which can be on port C (**XMEGA_SPI_PORT_C**) or on port D (**XMEGA_SPI_PORT_D**). * * Call the **__start_timer()** to start the millisecond timer. * * @note Note about the millisecond functionality:
* * The millisecond functionality is based on the TCE0 so don't use these pins as IO.
* The operating frequency of the uC is 32MHz. If you have other frequency change the TCE0 registers appropriatly in function **__start_timer()** in **compatibility.c** file for your frequency. * * @page Portability RF24 Portability * * The RF24 radio driver mainly utilizes the Arduino API for GPIO, SPI, and timing functions, which are easily replicated * on various platforms.
Support files for these platforms are stored under RF24/utility, and can be modified to provide * the required functionality. * *
* @section Hardware_Templates Basic Hardware Template * * **RF24/utility** * * The RF24 library now includes a basic hardware template to assist in porting to various platforms.
The following files can be included * to replicate standard Arduino functions as needed, allowing devices from ATTiny to Raspberry Pi to utilize the same core RF24 driver. * * | File | Purpose | * |--------------------|------------------------------------------------------------------------------| * | RF24_arch_config.h | Basic Arduino/AVR compatibility, includes for remaining support files, etc | * | includes.h | Linux only. Defines specific platform, include correct RF24_arch_config file | * | spi.h | Provides standardized SPI ( transfer() ) methods | * | gpio.h | Provides standardized GPIO ( digitalWrite() ) methods | * | compatibility.h | Provides standardized timing (millis(), delay()) methods | * | your_custom_file.h | Provides access to custom drivers for spi,gpio, etc | * *
* Examples are provided via the included hardware support templates in **RF24/utility**
* See the modules page for examples of class declarations * *
* @section Device_Detection Device Detection * * 1. The main detection for Linux devices is done in the configure script, with the includes.h from the proper hardware directory copied to RF24/utility/includes.h
* 2. Secondary detection is completed in RF24_config.h, causing the include.h file to be included for all supported Linux devices
* 3. RF24.h contains the declaration for SPI and GPIO objects 'spi' and 'gpio' to be used for porting-in related functions. * *
* @section Ported_Code Code * To have your ported code included in this library, or for assistance in porting, create a pull request or open an issue at https://github.com/TMRh20/RF24 * * *


*/ #endif // __RF24_H__